RU2678645C2 - Touch control substrate, terminal and method of improving touch accuracy - Google Patents

Abstract

FIELD: means of touch control.SUBSTANCE: group of inventions relates to the means of touch control. To this end, a touch control substrate is proposed, which comprises a logic control module, a touch control module, a first switching control module, the first switching module, the second switching module, the second switching control module and the electrode module. Logic control module is connected respectively to the first switching control module, the sensor control module and the second switching module. First switching module is connected respectively to the first switching control module, the sensor control module, the second switching module and the electrode module. Second switching module is additionally connected to the second switching control module, the sensor control module and the electrode module.EFFECT: technical result – improved touch accuracy of the touch panel.12 cl, 4 dwg

Description

FIELD OF THE INVENTION

[0001] The present invention relates to the field of communication methods, and in particular to a touch control substrate, a contact clip, and a method for improving touch accuracy.

BACKGROUND OF THE INVENTION

[0002] Currently, the method for scanning capacitive panel mainly includes a method for scanning its own capacitance and a method for scanning mutual capacitance. Scanning the self-capacitance consists in simultaneously scanning the row electrode and the column electrode to determine the self-capacitance of the row electrode and the self-capacitance of the column electrode (i.e., to determine the change in capacitance generated between the row electrode and the touching finger or between the column electrode and the touching finger). Mutual capacitance scanning is a corresponding sequential scan of row electrodes and column electrodes to determine the mutual capacitance between two electrodes perpendicular to each other (i.e., to determine the change in capacitance at the location of the intersection point of the row electrode and column electrode perpendicular to each other in the capacitive panel )

[0003] However, in the case of a large touch panel, dummy points (that is, touch points detected by the system by mistake) will occur due to the method of scanning the internal capacitance when there are two or more points on the large size touch panel touch, and the scanning speed is low when the mutual capacitance scanning method is applied.

[0004] For example, when two points are touched, four points of contact will be determined by the system, because the self-capacitance scanning method scans the X electrode and the Y electrode simultaneously. However, only two points of tangency are real points of tangency, the other two points of tangency are fictitious points.

[0005] The scanning method of mutual capacitance should sequentially scan rows (Y-electrodes), and then sequentially scan columns (X-electrodes), and it determines the actual touch points in accordance with the scan time of Y-electrodes and the capacitance between X-electrodes and Y - electrodes perpendicular to each other. Since the mutual capacitance scanning method must sequentially scan rows and columns, the time to determine the points is long, and the point report is inefficient for a large capacitive panel, although the touch points obtained by the mutual capacitance scanning method are real touch points.

SUMMARY OF THE INVENTION

[0006] The main technical problem solved by the present application is to provide a touch control substrate, a contact clip and a method for improving touch accuracy to eliminate fictitious points, improve the accuracy of detection of touch points, a method characterized by a high scanning speed.

[0007] In order to solve the technical problem mentioned above, one technical solution adopted by the present application is a touch control substrate, the touch control substrate comprising a logical control module, a touch control module, a first switching control module, a first switching module, a second switching module a second switching control module and an electrode module; moreover, the logical control module contains a first output, a second output and a third output, a touch control module contains a control output, a first generating output, a second generating output and receiving input, a first switching control module contains input and output, a first switching module contains a control output, first input , a second input and output, a second switching module comprises a control output, a first input, a second input and an output, a second switching control module comprises an input and an output; the first output of the logical control unit is connected to the output of the first switching control unit, and the output of the first switching control unit is connected to the control output of the first switching unit; the second output of the logical control module is connected to the control output of the touch control module, the first forming output of the touch control module is connected to the first input of the first switching module, the second forming output of the touch control module is connected to the second input of the first switching module, and the output of the first switching module is connected to the block electrodes row electrodes module; the third output of the logical control module is connected to the input of the second switching control module, and the output of the second switching control module is connected to the control terminal of the second switching module; the first input of the second switching module is connected to the first input of the first switching module, the second input of the second switching module is connected to the electrode block of the column of the electrode module, and the output of the second switching module is connected to the receiving input of the touch control module;

the logic control module generates a first trigger signal to trigger the first switching control module to control the connection of the first input of the first switching module to the output of the first switching module and to trigger the touch control module to output the first scan signal to the electrode module through the first switching module to scan the electrode’s own capacitance Rows and generates a first control signal for controlling the second switching control module for controlling the connection of the first input of the second switching module to the output of the second switching module for transmitting the signal of the electrode of the electrode module row to the touch control module through the first switching module and the second switching module to determine the electrode of the line when the signal changes in electrode module; and the logic control module further generates a second trigger signal when the electrode module completes the scan of its own capacitance to start the first switching control module to control the connection of the second input of the first switching module to the output of the first switching module; generates a second control signal for controlling the touch control module for outputting a second scan signal to the electrode module through the first switching module to scan the mutual capacitance on a specific row electrode; and generates a third control signal for controlling the second switching control module for controlling the connection of the second input of the second switching module to the output of the second switching module for transmitting the electrode signal of the column of the electrode module to the touch control module through the second switching module to determine the location when the signal in the electrode module changes so that get the coordinate of the touch point.

[0008] Moreover, the electrode module comprises a row electrode block and a column electrode block, a row electrode block contains a plurality of row electrodes, and a column electrode block contains a plurality of column electrodes; the first switching module contains a plurality of first switches, each of the first switches corresponding to one of the row electrodes, the first switches containing the first inputs, second inputs and outputs, the first inputs are connected respectively to the first forming output of the touch control module, the second inputs are connected respectively to the second forming output touch control module, and the findings are connected respectively to the row electrodes; and the second switching module comprises a plurality of second switches, each of the second switches corresponding to one of the column electrodes, the second switches containing first inputs, second inputs and outputs, first inputs of second switches connected respectively to first inputs of first switches, second inputs of second switches connected respectively with the electrodes of the column, and the terminals of the second switches are connected respectively to the receiving input of the touch control module.

[0009] In order to solve the technical problem mentioned above, another technical solution adopted by the present application is to provide a touch control substrate, the touch control substrate comprising a logic control module, a touch control module, a first switching control module, a first switching module, a second switching module, a second switching control module and an electrode module; the logical control module is connected respectively to the first switching control module, the touch control module and the second switching control module; the first switching module is connected respectively to the first switching control module, the touch control module, the second switching module and the electrode module; the second switching module is further connected to the second switching control module, the touch control module and the electrode module; the logical control module generates a first trigger signal for triggering the first switching control module for controlling the switching of the first switching module to its first configuration and for triggering the touch control module for outputting the first scan signal to the electrode module through the first switching module to scan its own row electrode capacitance; and generates a first control signal for controlling the second switching control module to control the switching of the second switching module to its first configuration for transmitting the electrode signal of the electrode module row to the touch control module through the first switching module and the second switching module to determine the electrode of the row when the signal in the electrode module changes; and the logic control module further generates a second trigger signal when the electrode module finishes scanning its own capacitance to trigger the first switching control module to control the switching of the first switching module to its second configuration; generates a second control signal for controlling the touch control module for outputting a second scan signal to the electrode module through the first switching module to scan the mutual capacitance on a specific row electrode; and generates a third control signal for controlling the second switching control module for controlling the switching of the second switching module to its second configuration for transmitting the electrode signal of the column of the electrode module to the touch control module through the second switching module to determine the location when the signal in the electrode module changes to obtain the point coordinate touch.

[0010] Moreover, the logical control module contains a first output, a second output and a third output, a touch control module contains a control output, a first generating output, a second generating output and receiving input, a first switching control module contains input and output, a first switching module contains a control the output, the first input, the second input and output, the second switching module contains a control output, the first input, the second input and output, the second switching control module contains input and output; the first output of the logical control module is connected to the input of the first switching control module, and the output of the first switching control module is connected to the control terminal of the first switching module; the second output of the logical control module is connected to the control output of the touch control module, the first forming output of the touch control module is connected to the first input of the first switching module, the second forming output of the touch control module is connected to the second input of the first switching module, and the output of the first switching module is connected to the block electrodes row electrodes module; the third output of the logical control module is connected to the input of the second switching control module, and the output of the second switching control module is connected to the control terminal of the second switching module; and the first input of the second switching module is connected to the first input of the first switching module, the second input of the second switching module is connected to the electrode unit of the column of the electrode module, and the output of the second switching module is connected to the receiving input of the touch control module.

[0011] Moreover, the electrode module includes a row electrode block and a column electrode block, a row electrode block contains a plurality of row electrodes, and a column electrode block contains a plurality of column electrodes; the first switching module comprises a plurality of first switches, each of the first switches corresponding to one of the row electrodes, the first switches containing first inputs, second inputs and outputs, first inputs respectively connected to a first forming terminal of a touch control module, second contact terminals connected respectively to a second forming the output of the touch control module, and the findings are connected respectively to the electrodes of the line; and the second switching module comprises a plurality of second switches, each of the second switches corresponding to one of the column electrodes, the second switches containing first inputs, second inputs and outputs, first inputs of second switches respectively connected to first inputs of first switches, second inputs of second switches connected to electrodes of the column, and the findings of the second switches are connected respectively to the receiving input of the touch control module.

[0012] Moreover, the logic control module generating the first trigger signal for starting the first switching control module for controlling the switching of the first switching module to its first configuration is that the logic control module generates the first trigger signal for starting the first switching control module for controlling connecting the first input of the first switching module to the output of the first switching module; the logical control module generating the first control signal for controlling the second switching control module for controlling the switching of the second switching module to its first configuration is that the logical control module generates a first control signal for controlling the connection of the first input of the second switching module to the output of the second switching module ; the logic control module generating the second trigger signal when the electrode module completes scanning its own capacitance to start the first switching control module for controlling the switching of the first switching module to its second configuration is that the logic control module generates a second trigger signal when the electrode module completes the scan of its own capacitance to start the first switching control module to control the connection of the second input first switching unit with the output of the first switching module; and a logic control module generating a third control signal for controlling the second switching control module for controlling the switching of the second switching module to its second configuration, the logical control module generating a third control signal for controlling the second switching control module for controlling the second input connection of the second a switching module with the output of the second switching module.

[0013] To solve the technical problem mentioned above, another technical solution adopted by the present application is to provide a terminal that includes a touch control substrate and a capacitive touch panel described in any paragraph above.

[0014] In order to solve the technical problem mentioned above, another technical solution adopted by the present application is to propose a method for improving the accuracy of touch of the touch panel, which includes operating the terminal in the self-capacitance mode to scan its own capacitance on the touch panel row sensor to receive data from the line sensor when the signal changes; and switching the contact clamp to the mutual capacitance mode after completing the scan of the self capacitance to scan the mutual capacitance in accordance with the row sensor data when the signal changes to determine the coordinate of the touch point.

[0015] Moreover, the operation step of the contact clamp in the self-capacitance mode for scanning the self-capacitance on the row sensor of the touch panel to receive data from the row sensor when the signal changes includes the operation of the contact clamp in the self-capacitance mode for scanning the self-capacitance on the row sensor to determine line sensor signal values; and receiving data from the row sensor when the value of the row sensor signal changes.

[0016] Moreover, the step of switching the contact clamp to the mutual capacitance mode after scanning the self-capacitance to scan the mutual capacitance in accordance with the row sensor data when changing the signal to determine the coordinates of the touch point includes switching the contact clamp to the mutual capacitance mode after completing the scan of the self-capacitance to scan the mutual capacitance on the line sensor when the signal changes in accordance with the data from the line sensor to determine signal start between the row sensor and the column sensor; positioning when the signal changes in accordance with the signal value between the row sensor and the column sensor; and determining the coordinates of the touch point in accordance with the location.

[0017] Moreover, the step of switching the contact clamp to the mutual capacitance mode after scanning its own capacitance to scan the mutual capacitance on the row sensor when changing the signal in accordance with the row sensor to determine the signal value between the row sensor and the column sensor involves switching the terminal to mutual capacitance mode after completing scanning of its own capacitance for sequential execution of mutual capacitance on a plurality of row sensors when changing a signal for sequentially determining a signal value between each of the row sensors and the column sensor; and the step of determining the location when the signal changes in accordance with the signal value between the row sensor and the column sensor includes sequentially determining each of the plurality of locations when the signal changes in accordance with the signal values between the row sensors and the column sensor.

[0018] Moreover, the signal value is a voltage value or a capacitance value.

[0019] The effectiveness of the present application is that, in contrast to the prior art, the present application determines a row electrode when changing a signal by scanning its own capacitance on the row electrodes, and then scans the mutual capacitance on the row electrode when the signal changes and determines the coordinate of the touch point depending on the location when the signal changes between the row electrode and the column electrode. Therefore, this application eliminates fictitious points, improves the accuracy of detection of touch points and is characterized by a high scanning speed.

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] FIG. 1 is a schematic diagram of a touch control substrate in accordance with one embodiment of the present application.

[0021] FIG. 2 is a schematic diagram of a touch control substrate in accordance with another embodiment of the present application.

[0022] FIG. 3 is a flowchart of a method for improving touch accuracy in accordance with one embodiment of the present application.

[0023] FIG. 4 is a flowchart of a method for improving touch accuracy in accordance with another embodiment of the present application.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0024] The description below, which is intended to be an explanation, but not limitation, contains detailed information such as a specific system architecture, interface, method, etc. for a complete understanding of this application. However, those skilled in the art should be aware that the present application can be achieved by other embodiments without these details. In other situations, a detailed description of the known device, circuit and method is omitted, so that the description of the present application will not depend on unnecessary details.

[0025] See FIG. 1, which is a circuit diagram of a touch control substrate in accordance with one embodiment of the present application. The touch control substrate of the present application comprises a logic control module 110, a touch control module 120, a first switching control module 130, a first switching module 140, a second switching module 150, a second switching control module 160, and an electrode module 170.

[0026] The logic control module 110 is connected respectively to the first switching control module 130, the touch control module 120 and the second switching control module 160. The first switching module 140 is connected respectively to the first switching control module 130, the touch control module 120, the second switching module 150 and electrode module 170.

[0027] The second switching module 150 is further connected to the second switching control module 160, the touch control module 120, and the electrode module 170.

[0028] The logic control module 110 generates a first trigger signal to trigger the first switching control module 130 to control the switching of the first switching module 140 to its first configuration and to trigger the touch control module 120 to output the first scan signal to the electrode module 170 through the first switching module 140 to perform a scan of its own capacitance on the row electrode; and generates a first control signal for controlling the second switching control module 160 for controlling the switching of the second switching module 150 to its first configuration for transmitting the row electrode signal of the electrode module 170 to the touch control module 120 through the first switching module 140 and the second switching module 150 for determining the row electrode when changing the signal in the electrode module 170.

[0029] The logic control module 110 further generates a second trigger signal when the electrode module 170 completes scanning its own capacitance to start the first switching control module 130 to control the switching of the first switching module 140 to its second configuration; generates a second control signal for controlling the touch control module 120 to output a second scan signal to the electrode module 170 through the first switching module 140 to scan the mutual capacitance on a specific row electrode; and generates a third control signal for controlling the second switching control module 160 to control the switching of the second switching module 150 to its second configuration for transmitting the column electrode signal of the electrode module 170 to the touch control module 120 through the second switching module 150 to determine the location when the signal in the electrode module changes 170 to get the coordinate of the touch point.

[0030] In particular, after feeding the touch control substrate, the logic control module 110 generates a first trigger signal to the first switching control module 130 and the touch control module 120 to start the first switching control module 130 to control the switching of the first switching module 140 to its first configuration so that switch the operating mode of the touch control substrate to the scanning mode of its own capacity.

[0031] After the first switching module 140 is switched to its first configuration, the touch control module 120 is started to output the first scan signal to the electrode module 170 through the first switching module 140 to scan its own capacitance on the row electrode. After that, the logical control unit 110 generates a first control signal to the second switching control unit 140 to control the radiation of the second command switching unit 160 to the second switching unit 150 to switch the second switching unit 150 to its first configuration so that the touch control unit 120 receives the line electrode signal from the electrode module 170 through the first switching module 140 and the second switching module 150 to determine the row electrode when the signal in the module changes electrodes 170.

[0032] Moreover, the operation mode of the touch control module includes a scanning mode of its own capacitance and a scanning mode of mutual capacitance. The first configuration of the first switching module 140 and the first configuration of the second switching module 150 correspond to the scanning mode of its own capacitance. The second configuration of the first switching module 140 and the second configuration of the second switching module 150 correspond to the scanning mode of the mutual capacitance.

[0033] When the touch control substrate operates in self-capacitance mode, the first switching module 140 and the second switching module 150 switch to the first configuration; and the touch control module 120 generates a scan signal to the row electrode of the electrode module 170 through the first switching module 140 to simultaneously scan all row electrodes and receives all the row electrode signals through the second switching module 150 to recognize changes in the row electrode signals. Moreover, each change in the signal of the row electrode is a change in the intrinsic capacitance of the signal of the row electrode, and the signal of the row electrode can be a capacitance value or a voltage value.

[0034] When the electrode module 170 completes the scan of its own capacitance, the logic control module 110 generates a second trigger signal to the first switching control module 130 to start the first switching control module 130 to control the first switching module 140 to switch to the second configuration to switch the substrate operating mode touch control from scanning of its own capacity to scanning mode of its own capacity.

[0035] After switching the first switching module 140 to the second configuration, the logic control module 110 generates a second control signal and a third control signal to the touch control module 120, so that after receiving the second control signal, the touch control module 120 outputs a second scan signal to the electrode module 170 through a first switching module 140 for performing a scan of the mutual capacitance at the specific electrodes of the string when the signal changes; at the same time, after receiving the third control signal, the second switching control module 160 controls the second switching module 150 to switch to the second configuration, so that the touch control module 120 receives the mutual capacitance when the signal changes in the electrode module 170 through the second switch 150 to determine the location when changing the signal between the row electrode and the column electrode to obtain the coordinate of the touch point.

[0036] Moreover, when the touch control substrate operates in the mutual capacitance mode, the first switching module 140 switches to the second configuration, the second switching module 150 switches to the second configuration, and the touch control module 120 generates a second scan signal to the electrode of the row of the electrode module 170 through the first a switching module 140 and receives a signal between each row electrode and a column electrode through a second switching module 150 to recognize a signal change between each electrode with lines and electrode column.

[0037] It is understood that the scan frequencies of the first scan signal and the second scan signal can be set in accordance with user requirements and are not limited here.

[0038] The solution described above determines the row electrode when changing the signal by scanning its own capacitance on the row electrodes, then scans the mutual capacitance on the row electrode when changing the signal and determines the coordinate of the touch point depending on the location when changing the signal between the row electrode and column electrode. Therefore, the solution eliminates fictitious points, improves the accuracy of detection of touch points and is characterized by a high scanning speed.

[0039] See FIG. 2, which is a schematic diagram of a touch control substrate in accordance with another embodiment of the present application. The touch control substrate of the present application comprises a logical control module 110, a touch control module 120, a first switching control module 130, a first switching module 140, a second switching module 150, a second switching control module 160, and an electrode module 170. Moreover, the first switching module 140 comprises a plurality the first switches 141, the second switching module 150 comprises a plurality of second switches 151. The electrode module 170 comprises an electrode block of a row 171 and an electrode block of a column 172, to the electrodes of the row 171 contains many electrodes of the row, and the block of electrodes of the column 172 contains many electrodes of the column. The first switches 141 alternately correspond to the electrodes of the row, and the second switches 151 alternately correspond to the electrodes of the column.

[0040] The logic control module 110 comprises a first output, a second output and a third output, a touch control module 120 comprises a control output, a first generating output, a second generating output and receiving input, a first switching control module 130 comprising input and output, a first switching module 140 contains the control output, the first input 1, the second input 2 and output 3, the second switching module 150 contains the control output, the first input 1, the second input 2 and output 3, the second switching control module 160 contains input and output.

[0041] The first output of the logic control module 110 is connected to the output of the first switching control module 130, and the output of the first switching control module 130 is connected to the control terminal of the first switching module 140.

[0042] The second output of the logic control module 110 is connected to a control output of the touch control module 120, the first generating output of the touch control module 120 being connected to the first input 1 of the first switching module 140, the second generating output of the touch control module 120 is connected to the second input 2 of the first switching module 140, and the output of the first switching module 140 is connected to the electrode block row 171 of the electrode module 170.

[0043] The third output of the logic control module 110 is connected to the input of the second switching control module 160, and the output of the second switching control module 160 is connected to the second switching module 150.

[0044] The first input 1 of the second switching module 150 is connected to the first input 1 of the first switching module 140, the second input 2 of the second switching module 150 is connected to the electrode block of the column 172 of the electrode module 170, and the terminal 3 of the second switching module 160 is connected to the receiving input of the touch module control 120.

[0045] Moreover, the first switching module 140 comprises a plurality of first switches 141, each of the first switches 141 corresponding to one row electrode. The first switch 141 comprises a first input 1, a second input 2 and a terminal 3. The first input 1 of each first switch 141 is connected respectively to the first forming terminal of the touch control module 120, the second input 2 of each first switch 141 is connected respectively to the second forming terminal of the touch control module 120 and the output of each first switch 141 is connected respectively to the row electrode.

[0046] The second switching module 150 comprises a plurality of second switches 151, each of the second switches 151 corresponding to one column electrode. Moreover, the second switch 151 contains the first input 1, the second input 2 and terminal 3. The first input 1 of each second switch 151 is connected respectively to the first input 1 of the first switch 141, the second input 2 of each second switch 151 is connected respectively to the column electrode, and the output of each second the switch 151 is connected respectively to the receiving input of the touch control module 120.

[0047] The logic control module 110 generates a first trigger signal to trigger the first switching control module 130 to control the first input connection of the first switching module 140 to the output of the first switching module 140 and to trigger the touch control module 120 to output the first scan signal to the electrode module 170 via a first switching module 140 for scanning its own capacitance at the row electrodes; and generates a first control signal for controlling the second switching control module 160 for controlling the first input connection of the second switching module 150 with the output of the second switching module for transmitting the electrode signal of the electrode module 170 line to the touch control module 120 through the first switching module 140 and the second switching module 150 for determining the electrode of the line when the signal changes in the electrode module 170.

[0048] The logic control module 110 further generates a second trigger signal when the electrode module 170 completes scanning its own capacitance to start the first switching control module 130 to control the second input connection of the first switching module 140 to the output of the first switching module 140; generates a second control signal for controlling the touch control module 120 to output a scan signal to the electrode module 170 through the first switching module 140 to scan the mutual capacitance on a specific row electrode; and generates a third control signal for controlling the second switching control module 160 for controlling the second input connection of the second switching module 150 to the output of the second switching module 150 for transmitting the column electrode signal of the electrode module 170 to the touch control module 120 through the second switching module 150 for determining location when changing the signal in the electrode module 170 to obtain the coordinate of the touch point.

[0049] In particular, after the touch control substrate is powered, the logic control module generates a first trigger signal to the first switch control module 130 and the touch control module 120 to start the first switch control module 130 to control the first input connection 1 of each first switch 141 in the first switch module 140 with output 3 of the first switch 141 to switch the operating mode of the touch control substrate to the scanning mode of its own capacity.

[0050] After the first input 1 of each first switch 141 in the first switching module 140 is connected to terminal 3, the touch control module 120 is started to output the first scan signal to the electrode module 170 through the first switching module 140 to scan its own capacitance on the electrode strings. After that, the logical control unit 110 generates a first control signal to the second switching control unit 150 for controlling radiation from the second command switching control unit 160 to the second switching module 150 for connecting the first input 1 of each second switch 151 in the second switching module 150 to the output 3 of the second switch 151 so that the touch control module 120 can receive the electrode signals of the row of the electrode module 170 through the first switching module 140 and the second switching module 150 d To determine the row electrode when the signal changes in the electrode module 170.

[0051] Moreover, the operation mode of the touch control substrate includes a scanning mode of its own capacitance and a scanning mode of mutual capacitance. The connection of the first input of the first switching module 140 with the output of the first switching module 140 and the connection of the first input of the second switching module 150 with the output of the second switching module 150 correspond to the scanning mode of its own capacity. The connection of the second input of the first switching module 140 with the output of the first switching module 140 and the connection of the first input of the second switching module 150 with the output of the second switching module 150 correspond to the scanning mode of mutual capacitance.

[0052] When the touch control substrate operates in self-capacitance mode, the first switching module 140 switches to the first configuration, and the second switching module 150 switches to the first configuration, and the touch control module 120 generates a scan signal to the electrodes of the row of the electrode module 170 through the first switching module 140 for simultaneously scanning all row electrodes and receiving all row electrode signals from the second switching module 150 to recognize changes in the electronic signals line rows. Moreover, each change in the signal of the row electrode is a change in the intrinsic capacitance of the signal of the row electrode, and the signal of the row electrode can be a capacitance value or a voltage value.

[0053] When the electrode module 170 completes the scan of its own capacitance, the logic control module 110 generates a second trigger signal to the first switching control module 130 to start the first switching control module 130 to control the second input 2 connection of each first switch 141 in the first switching module 140 with output 3 of the first switch 141 to switch the operation mode of the touch control substrate from the scanning mode of its own capacitance to the scanning mode of its own capacitance.

[0054] After the second input 2 of each first switch 141 in the first switching module 140 is connected to the terminal 3 of the first switch 141, the logic control module 110 generates a second control signal and a third control signal to the touch control module 120 so that the touch control module 120 brought a second scan signal to the electrode module 170 through the first switching module 140 to scan the mutual capacitance on a specific electrode of the line when the signal changes after the sensor receives the sensor th control of the second control signal; and at the same time, after receiving the third control signal, the second switching control module 160 controls the connection of the second input 2 of each second switch 151 in the second switching module 150 with the output 3 of the second switch 151, so that the touch control module 120 receives the mutual capacitance when the signal changes in the electrode module 170 through the second switch 150 to determine the location when the signal changes between the row electrode and the column electrode in the electrode module 170 to obtain the coordinate of the touch point .

[0055] Moreover, when the touch control substrate operates in the mutual capacitance mode, the second input of the first switching module 140 is connected to the output of the first switching module 140, the second input of the second switching module 150 is connected to the output of the second switching module 150, and the touch control module 120 forms a second a scanning signal to the electrode module 170 through the first switching module 140 in order to sequentially scan each row electrode, and receives a signal between each row electrode and the electrode m of the column through the second switching module 150 to recognize a signal change between each row electrode and the column electrode.

[0056] It is understood that the scan frequencies of the first scan signal and the second scan signal can be set in accordance with user requirements and are not limited here.

[0057] The solution described above determines the row electrode when changing the signal by scanning its own capacitance on the row electrodes, then scans the mutual capacitance on the row electrode when changing the signal and determines the coordinate of the touch point depending on the location when changing the signal between the row electrode and column electrode. Therefore, the solution eliminates fictitious points, improves the accuracy of detection of touch points and is characterized by a high scanning speed.

[0058] The present application further provides a terminal that includes a touch control substrate and a capacitive touch panel described in the above embodiments. See details that are not described here again in the above embodiments.

[0059] See FIG. 3, which is a flow diagram of a method for improving touch accuracy in accordance with one embodiment of the present application. An embodiment is performed by a terminal. A method for improving touch accuracy of a touch panel in accordance with the present embodiment includes the following steps:

[0060] S101: performing a scan of its own capacitance on a row sensor of the touch control panel when the terminal operates in its own capacitance mode to receive data from the row sensor when the signal changes.

[0061] When the terminal operates in the self-capacitance mode, it generates a first scan signal to the line sensor, scans the self-capacitance on the line sensor in the touch panel to simultaneously determine the capacitance value or self-capacitance voltage of each line sensor in the touch panel to obtain data from row sensors when the capacitance value changes or the voltage value changes. Moreover, the determination of the self-capacitance is to determine the capacitance value or the voltage value of the self-capacitance of the line sensor, and the data from the line sensor is the coordinate of the line sensor. The line sensor coordinate is used to determine the line in which the line sensor signal changes.

[0062] S102: after scanning its own capacitance, the terminal switches to the mutual capacitance mode to scan the mutual capacitance in accordance with the data of the line sensor (s) when the signal changes to determine the coordinate of the touch point.

[0063] After the determination of the self-capacitance is completed, the contact terminal switches to the mutual capacitance mode. The terminal generates a second scan signal to the line sensors when the signal changes in accordance with the line sensor data when the signal changes to scan the mutual capacitance on the line sensor when the capacitance value changes or the voltage value changes to determine the location when the signal between the line sensor changes, the capacitance value or value whose voltage varies, and the column sensor. When the terminal determines the location when the signal changes, get the location coordinate to determine the coordinate as the coordinate of the touch point.

[0064] For example, when the terminal scans its own capacitance on the row sensors and determines that the capacitance value or voltage value of the row sensors in the 1st row and the 5th row changes, the terminal will accordingly scan the mutual capacitance on the row sensors in 1- 1st row and 5th row in mutual capacitance mode to determine locations when the signal changes between the row sensors in the 1st row and 5th row and all the column sensors.

[0065] In this embodiment, the scan frequencies of the first scan signal and the second scan signal can be set according to user requirements and are not limited here.

[0066] The solution described above receives data from the line sensor when the signal changes by scanning its own capacitance on line sensors in the touch control panel, and then scans the mutual capacitance on data from the line sensor when changing the signal to determine the coordinate of the touch point. The solution is able to eliminate fictitious points, improve the accuracy of detection of touch points and is characterized by a high scanning speed.

[0067] See FIG. 4, which is a flow diagram of a method for improving touch accuracy in accordance with another embodiment of the present application. An embodiment is performed by a contact clip. A method for improving touch accuracy of a touch panel in accordance with the present embodiment includes the following steps:

[0068] S201: performing self capacitance determination on the row sensor of the touch control panel when the terminal operates in the intrinsic capacitance mode to determine a value of the row sensor signal.

[0069] The terminal operates in the self-capacitance mode and generates a first scan signal to the line sensor to scan the self-capacitance on the line sensor in the touch panel to determine the capacitance value or self-capacitance voltage of each line sensor in the touch panel. Moreover, the definition of self-capacitance should determine the value of the capacitance or the voltage value of the self-capacitance of the row sensor.

[0070] Step S202 is performed when the value of the row sensor signal changes, or, otherwise, step S201 is performed continuously.

[0071] S202: receiving data from the row sensor when the value of the row sensor signal changes.

[0072] When a change in capacitance value or self-capacitance voltage value of any row sensor is determined, data is obtained from the row sensor when the capacitance value changes or the voltage value changes. Moreover, the data of the line sensor is the coordinate of the line sensor. The line sensor coordinate is used to determine the line in which the line sensor signal changes.

[0073] S203: after the self-capacitance scan is completed, the terminal switches to the mutual capacitance mode to scan the mutual capacitance on the row sensors when the signal changes in accordance with the row sensor data to determine a signal value between the row sensor and the column sensor.

[0074] After the scan of the self-capacitance is completed, the terminal switches from the self-capacitance mode to the mutual capacitance mode, and the terminal generates a second scan signal to the line sensors when the capacitance value changes or the voltage value changes in accordance with the received line sensor data to determine the signal value between each a row sensor whose capacitance or voltage value changes, and a column sensor. The signal value is the capacitance value or voltage value.

[0075] S204: positioning when the signal changes in accordance with the signal value between the row sensor and the column sensor.

[0076] The terminal sequentially determines the location when the signal changes between each row sensor when the signal changes and the column sensors in accordance with the signal value between the row sensors and the column sensors.

[0077] S205: determining the coordinates of the touch point in accordance with the location.

[0078] When the terminal determines the locations where the signal changes between the row sensors and the column sensors, the coordinates of the locations are obtained so that the terminal sequentially determines the coordinates of the touch points sequentially in accordance with the coordinates of the locations where the signal changes between the row sensors and the column sensors.

[0079] In this embodiment, the scan frequencies of the first scan signal and the second scan signal can be set according to user requirements and are not limited here.

[0080] The solution described above receives data from the line sensor when the signal changes by scanning its own capacitance on line sensors in the touch control panel, and then scans the mutual capacitance on data from the line sensor when changing the signal to determine the coordinate of the touch point. The solution is able to eliminate fictitious points, improve the accuracy of detection of touch points and is characterized by a high scanning speed.

[0081] The description made above, which is intended to explain, but not limit, contains detailed information such as a specific system architecture, interface, method, etc. for a complete understanding of this application. However, those skilled in the art should be aware that the present application can be achieved by other embodiments without these special details. In other situations, a detailed description of the known device, circuit and method is omitted, so that the description of the present application will not depend on unnecessary details.

Claims (80)

1. The touch control substrate containing logic control module touch control module first switching control module, first switching module second switching control module, second switching module and electrode module; moreover, the logical control module contains a first terminal, a second terminal and a third terminal, the touch control module comprises a control input, a first generating output, a second generating output and receiving input, the first switching control module contains input and output, the first switching module contains control input, first input, second input and output, the second switching control module comprises input and output, the second switching module comprises control input, first input, second input and output; the first output of the logical control module is connected to the input of the first switching control module, and the output of the first switching control module is connected to the control input of the first switching module; the second output of the logical control module is connected to the control input of the touch control module, moreover, the first forming output of the touch control module is connected to the first input of the first switching module, the second forming output of the touch control module is connected to the second input of the first switching module, and the output of the first switching module is connected to the electrode block of the electrode module row; the third output of the logical control module is connected to the input of the second switching control module, and the output of the second switching control module is connected to the control input of the second switching module; the first input of the second switching module is connected to the first input of the first switching module, the second input of the second switching module is connected to the electrode block of the column of the electrode module, and the output of the second switching module is connected to the receiving input of the touch control module; the logical control module generates a first trigger signal to trigger the first switching control module to control the connection of the first input of the first switching module with the output of the first switching module, and also to start the touch control module for outputting the first scan signal to the electrode module through the first switching module to scan its own capacitance of the row electrode; and generates a first control signal for controlling the second switching control module for controlling the connection of the first input of the second switching module to the output of the second switching module for transmitting the signal of the electrode of the electrode module row to the touch control module through the first switching module and the second switching module to determine the electrode of the line when the signal changes in electrode module; and the logic control module further generates a second trigger signal when the electrode module completes the scan of its own capacitance to start the first switching control module to control the connection of the second input of the first switching module to the output of the first switching module; generates a second control signal for controlling the touch control module for outputting a second scan signal to the electrode module through the first switching module to scan the mutual capacitance on a specific row electrode; and generates a third control signal for controlling the second switching control module for controlling the connection of the second input of the second switching module to the output of the second switching module for transmitting the electrode signal of the column of the electrode module to the touch control module through the second switching module to determine the location when the signal in the electrode module changes so that get the coordinate of the touch point. 2. The touch control substrate according to claim 1, characterized in that the electrode module comprises a row electrode block and a column electrode block, a row electrode block contains a plurality of row electrodes, and a column electrode block contains a plurality of column electrodes; the first switching module contains a plurality of first switches, each of the first switches corresponding to one of the row electrodes, the first switches containing the first inputs, second inputs and outputs, the first inputs are connected respectively to the first forming output of the touch control module, the second inputs are connected respectively to the second forming output touch control module, and the findings are connected respectively to the row electrodes; and the second switching module comprises a plurality of second switches, each of the second switches corresponding to one of the column electrodes, the second switches containing first inputs, second inputs and outputs, first inputs of the second switches connected respectively to the first inputs of the first switches, second inputs of the second switches connected respectively to electrodes of the column, and the findings of the second switches are connected respectively to the receiving input of the touch control module. 3. A touch control substrate, the touch control substrate comprising a logic control module, a touch control module, a first switching control module, a first switching module, a second switching module, a second switching control module and an electrode module; the logical control module is connected respectively to the first switching control module, the touch control module and the second switching control module; the first switching module is connected respectively to the first switching control module, the touch control module, the second switching module and the electrode module; the second switching module is further connected to the second switching control module, the touch control module and the electrode module; the logical control module generates a first trigger signal to trigger the first switching control module to control the switching of the first switching module to its first configuration and to start the touch control module for outputting the first scan signal to the electrode module through the first switching module to scan its own capacitance of the row electrode; and generates a first control signal for controlling the second switching control module to control the switching of the second switching module to its first configuration for transmitting the electrode signal of the electrode module row to the touch control module through the first switching module and the second switching module to determine the electrode of the row when the signal in the electrode module changes; and the logical control module further generates a second trigger signal when the electrode module completes the scan of its own capacitance to start the first switching control module to control the switching of the first switching module to its second configuration; generates a second control signal for controlling the touch control module for outputting a second scan signal to the electrode module through the first switching module to scan the mutual capacitance on a specific row electrode; and generates a third control signal for controlling the second switching control module for controlling the switching of the second switching module to its second configuration for transmitting the electrode signal of the column of the electrode module to the touch control module through the second switching module to determine the location when the signal in the electrode module changes to obtain the point coordinate touch. 4. The substrate for touch control according to claim 3, characterized in that the logical control module comprises a first output, a second output and a third output, the touch control module contains a control input, the first forming output, the second forming output and receiving input, the first switching control module comprises input and output, the first switching module comprises a control input, a first input, a second input and output, the second switching module comprises a control input, a first input, a second input and output, the second switching control module comprises input and output; the first output of the logical control module is connected to the input of the first switching control module, and the output of the first switching control module is connected to the control input of the first switching module; the second output of the logical control module is connected to the control input of the touch control module, the first forming output of the touch control module is connected to the first input of the first switching module, the second forming output of the touch control module is connected to the second input of the first switching module, and the output of the first switching module is connected to the block electrodes row electrodes module; the third output of the logical control module is connected to the input of the second switching control module, and the output of the second switching control module is connected to the control input of the second switching module; and the first input of the second switching module is connected to the first input of the first switching module, the second input of the second switching module is connected to the electrode block of the column of the electrode module, and the output of the second switching module is connected to the receiving input of the touch control module. 5. The touch control substrate according to claim 3, characterized in that the electrode module comprises a row electrode block and a column electrode block, a row electrode block contains a plurality of row electrodes, and a column electrode block contains a plurality of column electrodes; the first switching module comprises a plurality of first switches, each of the first switches corresponding to one of the row electrodes, the first switches containing first inputs, second inputs and outputs, first inputs respectively connected to a first forming terminal of a touch control module, second contact terminals connected respectively to a second forming the output of the touch control module, and the findings are connected respectively to the electrodes of the line; and the second switching module contains many second switches, each of the second switches corresponding to one of the column electrodes, the second switches containing the first inputs, second inputs and outputs, the first inputs of the second switches are connected respectively to the first inputs of the first switches, the second inputs of the second switches are connected to the electrodes column, and the findings of the second switches are connected respectively to the receiving input of the touch control module. 6. The touch control substrate according to claim 3, characterized in that the logic control module generating the first trigger signal to trigger the first switching control module for controlling the switching of the first switching module to its first configuration includes: the logical control module is configured to generate a first trigger signal to trigger the first switching control module to control the connection of the first input of the first switching module to the output of the first switching module; a logical control module generating a first control signal for controlling a second switching control module for controlling a switching of the second switching module to its first configuration includes: the logical control module is configured to generate a first control signal for controlling the connection of the first input of the second switching module with the output of the second switching module; a logic control module generating a second trigger signal when the electrode module finishes scanning its own capacitance to start the first switching control module for controlling the switching of the first switching module to its second configuration includes: the logical control module is configured to generate a second trigger signal when the electrode module completes the scan of its own capacitance to start the first switching control module to control the connection of the second input of the first switching module to the output of the first switching module; and a logical control module generating a third control signal for controlling the second switching control module for controlling the switching of the second switching module to its second configuration includes: the logical control module is configured to generate a third control signal for controlling the second switching control module to control the connection of the second input of the second switching module to the output of the second switching module. 7. A terminal comprising a touch control substrate and a capacitive touch panel according to any one of paragraphs. 1-4. 8. A method for improving the accuracy of a touch of a touch panel, the method comprising: operation of the terminal in the self-capacitance mode to scan the self-capacitance on the row sensor of the touch panel to receive data from the row sensor when the signal changes; and switching the terminal to the mutual capacitance mode after completing the scan of its own capacitance to perform scanning of the mutual capacitance in accordance with the data of the line sensor when the signal changes to determine the coordinates of the touch point, characterized in that it includes providing a terminal touch control substrate including a logic control module, a touch control module, a first switching control module, a first switching module, a second switching control module, a second switching module and an electrode module, the logical control module being connected respectively to the first switching control module, the touch module control and a second switching control module; the first switching module is connected respectively to the first switching control module, the touch control module, the second switching module and the electrode module; the second switching module is further connected to the second switching control module, the touch control module and the electrode module; generating, by the logical control module, a first trigger signal for triggering the first switching control module for controlling the switching of the first switching module to its first configuration, and for triggering a touch control module for outputting the first scan signal to the electrode module through the first switching module to scan the row electrode's own capacitance; generating by the logical control module the first control signal for controlling the second switching control module for controlling the switching of the second switching module to its first configuration for transmitting the electrode signal of the electrode module line to the touch control module through the first switching module and the second switching module to determine the electrode of the line when the signal in the module changes electrodes; and generating by the logical control module a second triggering signal when the electrode module completes scanning its own capacitance to start the first switching control module to control the switching of the first switching module to its second configuration; generating by the logical control module a second control signal for controlling the touch control module for outputting a second scan signal to the electrode module through the first switching module to scan the mutual capacitance on a specific electrode of the line; and the logical control module generating a third control signal for controlling the second switching control module for controlling the switching of the second switching module to its second configuration for transmitting the electrode signal of the column of the electrode module to the touch control module through the second switching module to determine the location when the signal in the electrode module changes to obtain the coordinate of the touch point. 9. The method according to p. 8, characterized in that the stage of operation of the terminal in the self-capacitance mode for scanning its own capacitance on the line sensor of the touch panel to receive data from the line sensor when the signal changes includes: operation of the terminal in the self-capacitance mode for scanning its own capacitance at the line sensor to determine the signal value of the line sensor; and receiving data from the line sensor when the value of the line sensor signal changes. 10. The method according to p. 8, characterized in that the step of switching the terminal to the mutual capacitance mode after scanning its own capacitance for scanning the mutual capacitance in accordance with the data of the line sensor when changing the signal to determine the coordinates of the touch point includes: switching the terminal to the mutual capacitance mode after scanning its own capacitance for scanning the mutual capacitance on the row sensor when the signal changes in accordance with the data from the row sensor to determine the signal value between the row sensor and the column sensor; positioning when the signal changes in accordance with the signal value between the row sensor and the column sensor; and determining the coordinates of the touch point in accordance with the location. 11. The method according to p. 10, characterized in that the step of switching the terminal to the mutual capacitance mode after scanning its own capacitance to scan the mutual capacitance on the line sensor when the signal changes in accordance with the line sensor data to determine the signal value between the line sensor and the sensor column includes: switching the terminal to the mutual capacitance mode after scanning its own capacitance for sequentially performing mutual capacitance on a plurality of row sensors when the signal changes to sequentially determine the signal value between each of the row sensors and the column sensor; and the step of determining the location when the signal changes in accordance with the signal value between the row sensor and the column sensor includes: sequentially determining each of the plurality of locations when the signal changes in accordance with the signal values between the row sensors and the column sensor. 12. The method according to p. 11, characterized in that the signal value is a voltage value or a capacitance value.

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